The Nicotiana tabacum Mediator subunit MED25 regulates nicotine biosynthesis through interacting with the basic helix-loop-helix (bHLH) transcription factor NtMYC2s

Nicotine is one of the most important secondary metabolites in tobacco, and its biosynthesis can be induced by topping and jasmonic acid treatment. NtMYC2s play pivotal roles in the regulation of nicotine. The mediator server as a bridge betwen the transcription factors and RNA polymerase in order to facilitates transcription and functions in plants. However, the role of mediator in the regulation of nicotine biosynthesis remains unknown. In this study, we firstly identify the NtMED25 through homologous analysis. NtMED25 interacts with NtMYC2s through the MD region. Interestingly, the nicotine content is decreased in the the knock-down transgenic lines of NtMED25, and the expression levels of two nicotine biosynthesis genes, NtQPT2 and NtPMT2, are also reduced when compared with that in the wild-type plants. Furthermore, NtMED25 enhances the binding of NtMYC2a/ NtMYC2b to the promoter of NtPMT2 and NtQPT2, and then facilitates the nicotine biosynthesis. Therefore, our study revealed the function of mediator in the regulation of nicotine, and provide the insight role on the transcriptional regulation of plant secondary metabolites.

Protein-phosphatase NtPP2C2b and MAP-kinase NtMPK4 act in concert to modulate nicotine biosynthesis

Protein phosphatases (PPs) and protein kinases (PKs) regulate numerous developmental, defense, and phytohormone signaling processes in plants. However, the underlying regulatory mechanism governing biosynthesis of specialized metabolites, such as alkaloids, by the combined effects of PPs and PKs is insufficiently understood. Here, we report the characterization of a group B protein phosphatase type 2C (PP2C), NtPP2C2b, that likely acts upstream of the NICOTINE2 (NIC2) locus AP2/ERFs, to regulate nicotine biosynthesis in tobacco. Similar to the nicotine pathway genes, NtPP2C2b is highly expressed in roots and induced by jasmonate (JA). Overexpression of NtPP2C2b in transgenic hairy roots or stable transgenic tobacco plants repressed nicotine pathway gene expression and reduced nicotine accumulation. Additionally, transient overexpression of NtPP2C2b, together with the NtERF221, repressed transactivation of the quinolinate phosphoribosyltransferase (QPT) promoter in tobacco cells. We further demonstrated that the JA-responsive tobacco MAP Kinase 4 (NtMPK4) interacts with NtPP2C2b in yeast and plant cells. Conditional overexpression of NtMPK4 in tobacco hairy roots upregulated nicotine pathway gene expression and increased nicotine accumulation. Our findings suggest that a previously uncharacterized PP-PK module acts in concert to modulate alkaloid biosynthesis, highlighting the importance of posttranslational control in biosynthesis of plant specialized metabolites such as alkaloids.

Unravel the Mystery of NIC1-locus on Nicotine Biosynthesis Regulation in Tobacco

ABSTRACTBackgroundNicotine biosynthesis is mainly regulated by jasmonate (JA) signaling cascade in Nicotiana tabacum. As an allotetraploid species, the regulation of nicotine biosynthesis has been genetically verified via two unlinked NIC loci (named as NIC1 and NIC2) which are possibly originated from its two ancestral diploids. Previously, a N. tomentosiformis originated ethylene response factor (ERF) gene cluster was identified as the NIC2-locus which has been demonstrated positively regulates nicotine accumulation in N. tabacum.ResultsHere, we describe the genetic mapping of NIC1-locus, the major nicotine regulatory locus, by using a NIC1-locus segregating population through bulked segregant analysis. We identified two linkage marker TM23004 and TM22038 were delimited the NIC1-locus within a ~34.3-Mb genomic region at pseudochromosome 07 of tobacco genome. Genomic scan within this region revealed a NIC2-like locus ERF gene cluster exist in. To verify this ERF gene cluster is the genetically called “NIC1-locus”, different functional experiments based on most of the ERFs in regulating nicotine biosynthesis and their influences on alkaloid accumulations have been carried out. Collinearity analysis showed that NIC1-locus ERF genes are originated from N. sylvestris and exclusively expressed in root tissues. In addition, transcriptomic results indicate that NIC1-locus ERF genes are coexpressed with the NIC2-locus ERF genes and other nicotine biosynthetic genes and regulators after JA induction. Furthermore, the suppressed expression of four ERFs of the NIC1-locus genes corresponding with decreased NtPMT and NtQPT expression in NtMYC2-RNAi lines indicates the selected NIC1-locus ERFs function in downstream of NtMYC2 in the JA signaling cascades. In the meanwhile, the alkaloid levels are also determined by the amplitude of the four ERF gene expressions in both wild type and LA mutant. Additionally, in vitro binding assays, transient activation assays, and ectopic expression in transgenic plants demonstrate that these ERF genes are able to bind the GCC-box elements residing in the step-limiting gene promoters (such as NtPMT2, NtQPT2) and functional redundant but quantitatively transactivate nicotine biosynthetic gene expression. For nic1-locus mutation, two different sizes of deletions (nic1-S and nic1-B) were identified which occurred at the surrounding regions of the NIC1-locus gene cluster, which might disrupt, to some extent, chromosomal microenvironment and change gene expression around the deletion regions (including NIC1-locus ERFs), resulting in the decreased expression levels of NIC1-locus ERFs (such as NtERF199) and reduced alkaloid accumulation in the nic1-locus mutant.ConclusionsOur findings not only provide insight in to the mechanism of the NIC1-locus ERFs in the regulatory network of nicotine biosynthesis, but also unraveled the theoretical basis of the nic1-locus mutation in low nicotine mutant. These functional verified NIC1-locus ERF genes can be further used as potential target(s) for ethyl methanesulfonate-based mutagenesis to manipulate nicotine level in tobacco variety in tobacco breeding program.

Genetic Manipulation of Transcriptional Regulators Alters Nicotine Biosynthesis in Tobacco

The toxic alkaloid nicotine is produced in the roots of Nicotiana species and primarily accumulates in leaves as a specialized metabolite. A series of metabolic and transport genes involved in the nicotine pathway are coordinately upregulated by a pair of jasmonate-responsive AP2/ERF-family transcription factors, NtERF189 and NtERF199, in the roots of Nicotiana tabacum (tobacco). In this study, we explored the potential of manipulating the expression of these transcriptional regulators to alter nicotine biosynthesis in tobacco. The transient overexpression of NtERF189 led to alkaloid production in the leaves of Nicotiana benthamiana and Nicotiana alata. This ectopic production was further enhanced by co-overexpressing a gene encoding a basic helix-loop-helix-family MYC2 transcription factor. Constitutive and leaf-specific overexpression of NtERF189 increased the accumulation of foliar alkaloids in transgenic tobacco plants but negatively affected plant growth. By contrast, in a knockout mutant of NtERF189 and NtERF199 obtained through CRISPR/Cas9-based genome editing, alkaloid levels were drastically reduced without causing major growth defects. Metabolite profiling revealed the impact of manipulating the nicotine pathway on a wide range of nitrogen- and carbon-containing metabolites. Our findings provide insights into the biotechnological applications of engineering metabolic pathways by targeting transcription factors.

Transcriptome Analysis Reveals Key Genes Involved in the Regulation of Nicotine Biosynthesis at Early Time Points after Topping in Tobacco (Nicotiana tabacum L.)

Background： Nicotiana tabacum is an important economic crop. Topping, a common agricultural practice employed with flue-cured tobacco, is designed to increase leaf nicotine contents. Many genes are found to be differentially expressed in response to topping, particularly genes involved in nicotine biosynthesis, but comprehensive analyses of early transcriptional responses induced by topping are not yet available. To develop a detailed understanding of the mechanisms regulating nicotine biosynthesis after topping, we have sequenced the transcriptomes of N. tabacum roots at seven time points following topping. Results： Differential expression analysis revealed that 4,830 genes respond to topping across all time points. Amongst these, nine gene families involved in nicotine biosynthesis and two gene families involved in nicotine transport showed significant changes during the immediate 24 hour period following topping. No obvious preference to the parental species was detected in the differentially expressed genes (DEGs). Significant changes in transcript levels of nine genes involved in nicotine biosynthesis and phytohormone signal transduction were validated by qRT-PCR assays. 549 genes encoding transcription factors (TFs), found to exhibit significant changes in gene expression after topping, formed 15 clusters based on similarities of their transcript level time-course profiles. 336 DEGs involved in phytohormone signal transduction, including genes functionally related to the phytohormones jasmonic acid, abscisic acid, auxin, ethylene, and gibberellin, were identified at the earliest time point after topping. Conclusions： Our research provides the first detailed analysis of the early transcriptional responses to topping in N. tabacum , and identifies excellent candidates for further detailed studies concerning the regulation of nicotine biosynthesis in tobacco roots.